Telephone system including magnetic storage device



1962 M. A. CLEMENT 3,051,789

TELEPHONE SYSTEM mcwnm; MAGNETIC STORAGE DEVICE Filed Sept. 11, 1959 6 Sheets-Sheet 1 FIG.

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ALLOTTER o c SLEEVE\ RINGR 7 TIP INVENTOR. MILTON A. CLEMENT ATTORNEY Aug. 28, 1962 Filed Sept. 11, 1959 M. A. CLEMENT 6 Sheets-Sheet 6 6 ONE-TO-FIVE G-IO ABOVE FIVE I 5 PARTY MATRIX T0 PARTY SIX MATRIX I 0R6 SWITCHING CIRCUIT-600 6 TO 13g given L6 OTFI 1 2 0R 1 ,sAFa w I,son=2 EIGHT 4 0R9 THREE I1 I,e OTF 3 fi 5 on D INE 6FOUR b A 4 I,e OTF4 -I 6AF5 --1,soTI-'s Y 1 650 I I 660 I T 670 PRIVATE PARTY PARTY PARTY LINE AND MATRIX MATRIX MATRIX PER MATRIX s I 0 620 630 640 IDENTIFICATION MATRIX I CIRCUIT-680 IDENTIFIER CIRCUIT United States Patent 3,051,789 TELEPHONE SYSTEM lNCLUDmG MAGNETEC STORAGE DEVICE Milton A. Clement, Rochester, N.Y., assignor to General Dynamics Corporation, Rochester, N.Y., a corporation of Delaware Filed Sept. 11, 1959, Ser. No. 839,396 6 Claims. (Cl. 1797.1)

This invention relates to an automatic toll ticketing system and, more particularly, to a system of this type including new and improved magnetic recorder control means.

In the automatic toll ticketing system shown and described in the copending application of M. A. Clement and B. A. Harris, Serial No. 536,579, filed September 2 6, 1955, which application is assigned to the same assignee as the present application, items of information pertaining to toll calls successively placed over a trunk circuit are automatically recorded in a trunk recorder individual to the trunk circuit. These recording operations are controlled by certain components in the trunk circuit and are performed at different time intervals during the extension of the connection. The trunk recorder, which can be of the type shown in Gleason Patent No. 2,867,435, includes an endless loop of magnetic tape on which control and data representing signals are recorded. The endless loop of tape has a home position or effective beginning from which the tape is moved step-by-step as information is magnetically recorded thereon. This effective beginning or home position is defined by indicia carried on the tape, such as conductive foil segments or perforations.

In a system of the type shown in the above identified copending application, the trunk recorders associated with the trunks in a particular group are played back in sequence by a playback control circuit including switching means which sequentially seize each of the idle trunks and their associated recorders. The magnetic tape in the seized recorder is returned to its home position, and the stored information thereon is reproduced and transmitted to recorder facilities which provide a permanent record of the toll call data. This prior system also includes an advance circuit means for automatically advancing the record medium or magnetic tape in the trunk recorder next succeeding or following the seized trunk circuit to its eifective beginning or home position to reduce the holding time of the trunk circuit when this next succeeding trunk circuit is played back, each trunk circuit being busied out when seized or when the record medium has been advanced to its home position prior to seizure. This prior circuit arrangement essentially provides a series circuit linking the trunks a given group, so that, if a next succeeding trunk circuit is busy due to the performance of a data recording operation when the preceding trunk circuit is seized for playback, the series circuit homes the magnetic tape in the next idle trunk recorder and thus places three of the trunk circuits in the group in a busy condition. Under certain operating conditions, the number of busy trunks is such as to adversely affect the trailic handling capacity of the system.

Accordingly, one object of the present invention is to provide a new and improved trunk or adapter circuit.

Another object is to provide new and improved advance circuit means which prevents an excessive number of trunk circuits from being placed in a busy condition.

A further object is to provide an automatic toll ticketing system having a plurality of serially related magnetic recorders which are automatically and individually conditioned for operation by the seizure of a preceding recorder in the sequence and which are interlocked to ice prevent the conditioning of any further recorders when the recorder next following a seized recorder is engaged in storing toll call data.

A further object is to provide an automatic toll ticketing system including new and improved means for controlling the movement of the magnetic tape in each of a plurality of successively seized trunk recorders.

Other objects and advantages of the present invention will become apparent from the ensuing description of an illustrative embodiment thereof in the course of which reference is had to the acompanying drawings in which:

FIG. 1 is a block diagram illustrating conventional automatic telephone switching equipment in a local ofiice from which toll calls to be ticketed are extended;

FIGS. 2. to 5, inclusive, form a schematic drawing illustrating the details of a trunk circuit embodying the present invention;

FIG. 6 is a schematic diagram partially in block form illustrating a party matrix switching circuit in conjunction with other calling subscriber identifying equipment; and

FIG. 7 is a block diagram disclosing the manner in which FIGS. 2 to 6, inclusive, are positioned adjacent each other to form a complete circuit diagram of a system embodying the present invention.

In general, the trunk circuit of the present invention is adapted to be utilized in an automatic toll ticketing system of the type disclosed in the above identified copending Clement et al. application. As shown therein, the items of information pertaining to a toll call are collected in a trunk recorder or storage device individual to an outgoing toll trunk under the control of pulses dialed at a calling substation, the trunk recorders being capable of storing the items of information pertaining to a plurality of toll calls. At a selected time of day, such as the. early hours of the morning in which the traffic level on the system is relatively low, the trunk circuit is seized by recording and playback facilities to permit the items of information pertaining to a plurality of calls to be sequentially played back from the trunk recorder to control recording facilities for producing a group of permanent records each including the items of information pertaining to a single toll call.

More specifically and referring to FIGS. 1 to 6, inclusive, of the drawings, assuming that a toll call which is to be automatically ticketed is to be extended from a call ing substation A to a called substation B located in a remote area, the subscriber at the substation A goes olfhook to extend a circuit to a line circuit individual thereto, the line circuit 100 placing an allotter 101 in operation so that a link comprising a finder 102 and a selector 104- is placed in operation to search for and seize the calling line circuit 100. In response to the completion of the association between the finder-selector link including the units 102 and 104 with the line circuit 100, the calling subscribed is advised that dialing may be initiated to extend the connection to the called subscriber B. The first digit dialed at the calling substation A is an access digit which must be dialed in order to extend the connection tothe group of trunks equipped with automatic toll ticketing means which are utilized to extend the connection to the remote area. Assuming that the access digit is 8, in response to the dialing of the access digit 8, the selector 104 advances its wipers to the eighth level and thereafter automatically searches over the multiples in the eighth level to seize an idle outgoing trunk extending to the desired remote area. Assuming that the'trunk circuit shown in FIGS. 2 to 5, inclusive, is the first idle trunk circuit in the eighth level of the selector 104, the calling loop circuit is extended to this trunk circuit, thereby to prepare the trunk circuit for controlling the extension of the connection to the called substation B and for recording the items of information pertaining to the toll call in a trunk recorder 500 which is individual to this trunk circuit.

The first item of information dialed at the calling substation A following the seizure of an idle trunk circuit is a dialed party digit which has an arbitrary value if the calling substation A is on a private line, which has a value representing the units digit of the directory number of the calling substation if the substation A is on a terminal per line multiparty line, and which has a value corresponding to the position of thecalling substation A on a multiparty line if the multiparty service on the line is provided on a terminal per station basis. This dialed party digit is not repeated to remote switching equipment 300 but rather is simultaneously recorded in the trunk recorder or storage device 500 and utilized to control the setting of a stepping switch in the circuit. The final setting of the stepping switch operates a selected number of party digit register relays to prepare a single marking path on one of 'five conductors representing parties 1 or 6, 2 or 7, 3 or 8, 4 or 9, and 5 or lO'and to prepare a single marking path on a pair of conductors representing parties one to five or parties six'to ten. These conductors extend to a party matrix switching circuit 600 and control this circuit ata later point in the data recording process to select .a proper control component or party matrix for automatically determining the directory number of a calling substation on a terminal per station multiparty line. Foltlowing the completion of the dialing of the dialed party digit by the calling subscriber at the substation A, the stepping switch in the trunk circuit is returned to a normal condition and the trunk circuit is rendered capable of transmitting subsequently dialed digits to control the operation of the remote switching equipment 300 to extend the connection to the called subscriber B.

V The next item of information dialed by the subscriber at the stationrA is the group of digits forming the directory number of the called substation B, and, assuming that a conventional 2-5 numbering scheme is utilized, the subscriber at the station A dials seven digits, all of which are simultaneously recorded in the trunk recorder 500 and repeated over the outgoing trunk to the remote switching equipment 300, thereby to extend the connection to the called substation B. Simultaneously with thus utilizing the dialed digits representing the directory number of the called substation B, the trunk circuit advances the stepping switch therein in the interdigit interval so as to count the dialed switch operating digits so as to render the trunk circuit incapable of repeating additional digits over the outgoing trunk after a predetermined number of digits, i.e. seven, have been dialed.

In response to the receipt of answering supervisory signals from the remote switching equipment 300, a motor driven timing mechanism which is adapted to provide a control impulse at a selected time interval, such as one to two seconds, following the receipt of answering supervision and other pulses at one minute intervals representing elapsed time for the call is rendered effective so that, if the connection is not released within the first short time interval of from one to two seconds, the trunk circuit is advised that the call is to be ticketed and initiates the recording of date and time information in the trunk recorder 500. More specifically, the general system includes a clock-calendar circuit 220 of the type disclosed in the albove identified Clement et al. application which, upon actuation, provides a series of pulses representing the date and time on which the call being ticketed was placed, these pulses being recorded in the trunk recorder 500.

In response to the completion of the storage of the clock-calendar information. in the recorder 500, the trunk circuit applies ground to an identifier sender allotter (not shown) to initiate the automatic determination of the directory number of the calling substation A and the storage of this information in the trunk recorder 500. More specifically, the identifier sender allotter, which may be of the type disclosed in the above identified copending Clement et al. application, allots an idle one of a plurality of identifier senders, similar to an identifier sender 310, to the calling trunk circuit. The identifier sender 310 may be of the type disclosed in the above identified copending Clement et al. application or may be of the type disclosed in the copending application of Ben A. Harris, Serial No. 518,952, filed April 18, 1956, which application is assigned to the same assignee as the present application. In response to the completion of the association of the identifier sender 310 with the trunk circuit, a power supply circuit 210, which is also of the type disclosed in the above identified copending Clement et al. application, is rendered efiective to supply an identification potential over the HS lead of the extended switch train to selectively energize an identific-ation conductor 110 which is individual to the calling line circuit 100 and which terminates ina terminal 111. The terminal 111 is selectively connected to an identification matrix circuit 680, which is also of the type disclosed in the above identified copending Clement et al. application, in accordance with the type of service provided to the calling substation A. In the event that the substation A is on a private line, the terminal 111 is selectively interconnected with a private line and terminal per-line matrix 640 in accordance with the digits forming the directory number of the calling substation A. Also, if the calling substation A is located on a terminal per line multiparty line, the terminal 111 is connected'to the matrix 640 so as to provide marking conditions representing the thousands, hundreds, and tens digits of the directory number of the substation A, the units digit 'being pro vided 'by the dialed party digit as described above. If the calling substation A is located on a terminal per station multiparty line, the terminal 111 is connected in multiple to all of a plurality of ten party matrices of which only a party one matrix 610, a party two matrix 620, and a party three matrix 630 are shownin the draw,- ings so. that as many as ten separate marking conditions are established in the identification matrix circuit 680 in accordance with the different groups of digits forming the directory numbers of all of the substations on the terminal per station multiparty line on which the station A is located;

In the event'that the terminal 111 is connected to the private line and terminal per line matrix 640, the energization thereof selectively operates an identifier circuit 690, which may be of the type disclosed in either of the above identified copending Clement et al. or Harris applications, to provide marking conditions extending to the identifier sender 310 associated with the trunk circuit representing the digits forming the directory number of the calling substation on either the private line or the terminal per line multiparty line. Alternatively, if the calling substation A is located on a terminal per station multiparty line, marking conditions representing difierent designations are established in any number of the individual party matrices 610, 620', and 630. To determine the proper one of these matrices to be interconnected with the input to the identifier circuit 690, the party matrix switching circuit 600 is utilized. As described above, one or more of the group of the party register relays is selectively operated under the control of the stepping switch in the trunk'circuit in response to the dialing of the dialed party digit. In response to the receipt of information indicating that the identifier sender 310 has been associated with the trunk circuit, ground is applied to the paths prepared by the selective operation of the party register relays to selectively operate the party matrix switching circuit 600 so that only a single one of the ten party matrices including the matrices 610, 620, and 630 is cut through to the input of the identifier circuit, thereby to provide signals to the identifier sender 310 representing only a single one of the directory numbers in accordance with the position of the calling substation A on the terminal per station multiparty line.

In response to receiving calling subscriber designation digits from the identifier circuit 690, the identifier sender releases the identifier sender allotter, the identifier circuit 690, the identification matrix circuit 680, and the party matrix switching circuit 600, and removes the identification potential from the HS lead of the extended switch train and the identification conductor 11%, thereby to release the common equipment components for use in identifying a subscriber involved in a subsequently placed toll call. If satisfactory calling subscriber data is provided,

the identifier sender 31f) initiates the transmission of a series of pulses to the trunk recorder 50!) in accordance with the digital information stored in the sender 310 representing the designation of the calling substation A. However, if a satisfactory calling subscriber identification is not provided, the identifier sender 31E) prevents the continuation of the connection and arrests the recording of additional toll call data.

Following the completion of the transmission of the necessary information representing the directory number of the calling substation A, the identifier sender 310 is restored to its normal condition, and the timing device individual to the trunk circuit transmits duration impulses at one minute intervals which are stored in the storage device or trunk recorder 59% thereby to provide a record of the length of the toll call. When the connection is released, the storage of the duration impulses in the trunk recorder 59% is terminated, and the stepping switch, which has remained in a position representing the number of dialed switch extending digits, is restored to a normal position. This stepping switch thereafter cooperates with a pulse generating source in the trunk circuit to sequentially advance an elongated medium forming the record medium in the trunk recorder 530 through a series of steps which are counted by the stepping switch to provide a measured run-E for spacing the previously recorded items pertaining to the toll call just completed from the items of information pertaining to the next toll call placed through the trunk circuit. Prior to spacing out the elongated mediurn, the trunk recorder records an end-'of-call code on the elongated record medium representing the end of the item of information pertaining to the toll call. Following the completion of the spacing operation under the control of the stepping switch, the stepping switch is restored to its normal condition together with the remainder of the components in the trunk circuit, thereby to permit the trunk circuit to be utilized in controlling items of information pertaining to a plurality of subsequently extended toll calls.

To initiate a routine playback operation in which the items of information stored in a plurality of trunk recorders similar to the trunk recorder are transmitted to recording facilities 41%, which may be of the type disclosed in the above identified copending Clement et al. application, a start ground is forwarded to the recording means 416 at a selected time of day, preferably during the early morning hours, so that the recording means 419 is placed in operation to seize a playback control circuit 4%, which also may be of the general type disclosed in the above identified copending Clement et al. application. In response to seizure, the playback control circuit 400 places a switching means therein in operation to search for and sequentially seize the plurality of trunk circuits to which it has access. In seizing the first trunk circuit, this trunk circuit is operated to advance the magnetic tape in the recorder individual thereto to its effective beginning and thereafter movement of the magnetic tape under the control of the trunk circuit is terminated and transferred to the playback control circuit 4%. The playback control circuit 4%, working in conjunction with the recording facilities 410, intermittently advances the magnetic tape so that the items of information stored therein are transmitted to the recording facilities 410 to control the production of records, each of which relates to one of the complete calls whose data is recorded in the seized trunk recorder.

Incident to seizing the first trunk circuit, an advance circuit is completed extending to control means in the next trunk circuit to which the playback switching means has access, which control means, when operated, initiates the movement of the magnetic tape in the next succeeding trunk recorder to its effective beginning so that, when this next succeeding trunk circuit is seized, the delay inherent in advancing the magnetic tape to its effective beginning is obviated. The return of the magnetic tape to its home condition, however, places the trunk circuit in a busy condition, thus preventing its seizure for recording items of information pertaining to toll calls. In the prior trunk circuit disclosed in the above identified copending Clement et a1. application, the control means for advancing the magnetic tape to its effective beginning in advance of the seizure of the trunk circuit with which each of the trurk recorders is associated was such that, under certain operating conditions such as a busy condiiIlOIl of a given one or more of the trunk circuits, the advance circuit for returning the magnetic tape to its effective beginning was effectively extended to the first idle trunk circuit. In this manner, it was possible for virtually all of the trunk circuits in a given trunk group to be placed in a busycondition either due to the recording of the items of information or due to the return of the magnetic tapes to their effective beginning. Thus, with all of the trunk circuits in a busy condition for one reason or another, the traffic handling capabilities of the trunk group was materially reduced. Accordingly, in the trunk circuit of the present invention, the control means or advance circuit means for advancing the magnetic tapes in succeeding trunk circuits to their effective home positions is so arranged that, if any given trunk circuit is engaged in recording items of information pertaining to a toll call during the time in which a playback operation is being performed, the advance circuit for the next succeeding trunk circuit is interrupted to prevent placing an excessive number of trunk circuits in a busy condition. However, this series circuit arrangement is such that if the trunk circuit has been placed in a busy condition due to the manual operation of busying means or due to the establishment of an alarm condition in the trunk circuit, the series circuit relationship is maintained intact so that a trunk circuit which is busy for one of these reasons is effectively bypassed and the next succeeding idle trunk circuit is operated to returnthe magnetic tape in the trunk recorder individual thereto to its effective beginning.

Following the completion of the transmission of all of the items stored in any given one of the trunk recorders, the trunk circuit associated therewith first returns the magnetic tape to its effective beginning and thereafter renders the stepping switch and the pulse generating means therein effective to provide a measured run-off or a preselected distance between the effective beginning and the position on the elongated record medium at which the items of information pertaining to the first toll call are to be recorded. In response to the completion of the runoff operation, the trunk circuit is restored to a normal condition in which it is capable of being seized by line extending means and utilized in controlling the recording of items of information pertaining to toll calls. Following the completion of the playback of all of the trunk recorders associated with trunk circuits to which the play back control circuit has access, the playback control circuit 400 and the recording facilities 410 are restored to a normal condition.

It is often desirable, in providing proper maintenance for the toll ticketing facilities and including the trunk circuit, to dial the items of information pertaining to a test call directly into the trunk circuit, thereby to provide the trunk recorder 50% with the items of information pertaining to a test call, or to monitor the items of information being recorded in the trunk recorder 500 pertaining to a normal toll call; To permit the monitoring of items of information pertaining to a regularly established toll call, the trunk circuit is provided with test means permitting the connection of a monitoring or test device across the tip and ring conductors of the connection extended to the trunk circuit, thereby to audibly or visibly monitor the dialed information being supplied thereto. Alternatively, if it is desired to manually and directly insert information pertaining to a test call directly into the trunk circuit for recording by the trunk recorder 500, the test means are utilized in conjunction with a manually operated busy key, the conjoint operation of which permits a direct manually controlled recording of test cal-l data in the trunk recorder '00.

In the prior trunk circuits of the type disclosed in the above identified copending Clement et al. application, it is notpossible to directly dial test 'call information into the trunk recorder 500 inasmuch as, as described above, the trunk circuit is forcibly returned to a released condition in the event that the identifier sender 310 is not provided with a satisfactory calling line identification, and, since the provision of this information is dependent upon returning an identification potential over an extended switch train to the identification matrix 689, the recording of test call data produced by dialing directly into the trunk circuit would be interrupted at the recording of the calling subscriber designation because of the lack of an extended switch train to the trunk circuit. However, in the trunk circuit of the present invention, the test means includes means for supplying an identification potential directly from the trunk circuit to a preassigned test number in the private line and terminal per line matrix 640 so that, in response to operation of the testing means following the operation of a manually controlled busy means which prevents seizure of the trunk circuit, an artificial calling line designation is automatically supplied to the trunk circuit and to the trunk recorder 500 to'permit the recording of complete data pertaining to a test call.

To facilitate an easy understanding of the detached contact type of drawings utilized in the following description of an illustrative embodiment of the invention, a combined numerical and alphabetical designation has been utilized to identify many of the relay structures and manually operated keys forming the schematic diagram of the trunk circuit. The windings of the relays are identified by one or more numerical digits indicating the figures of the drawings on which the relay winding is to be found followed by a group of alphabetical characters designating the relay. The contacts pairs of the various relays in the schematic circuit diagram are designated by a composite alphabetical and numerical designation in which one or more numerical characters identifying the figure of the drawings on which the contact pair is located is followed by a group of alphabetical characters indicating the relay of which the contacts form a part. One or more numerical characters are added to this designation to individually designate the different contacts of the same relay appearing in a single figure of the drawmgs.

As an example, a calling bridge relay having an operating winding located in FIG. 3 of the drawings is designated 3CB, and the contacts of this relay which'are also located in FIG. 3 of the drawings are designated 3CB1 and 3CB2. Two other contact pairs forming a part of 6 contacts are located followed by the alphabetical characters identifying the key and one or more numerical characters individually designating the different contact pairs of the key which appear in the same figure of the drawings. For instance, an alarm key ALMK includes the pair of contacts 4ALMK1 'located in FIG. 4 of the drawings. 7 V

The remaining components in the schematic diagram are identified by solely numerical designations in which the digits other than the last two designate the figure of the drawings on which the element is located. For instance, the identifier sender 310 is located in FIG. 3 of the drawings, whereas the identifier circuit 690 is located in FIG. 6 of the drawings.

TRUNK RECORDER 500 The trunk recorder 560 is of the type disclosed in the copending application of Howard S. Gleason, Serial No.

378,209, filed September 3, 1953, which application is assigned to the same assignee as the present application. In general, the recorder 500 comprises a base plate on which is detachably mounted a magazine containing an endless loop of magnetic tape which is stored in random layer fashion. A portion of the magnetic tape, which is disposed outside of the magazine, is moved relative to a pair of transducing heads by one of a pair of driving means. The transducing heads comprise a record-reproduce space pulse head 549 and a record-reproduce mark pulse head 520' having two magnetic gaps which are disposed adjacent contiguous transversely spaced portions of the magnetic tape to define two separate channels for receiving mark and space pulse information. Another transducing head comprises an erase head 550 having a single gap which is adapted to erase the entire width or both channels of the magnetic tape.

During recording operations, the magnetic tape is stationary, and the first advancing means comprises a stepby-step advancing mechanism including a pawl and ratchet drive arrangement driven by an advance magnet 530 for advancing the magnetic tape through a very small distance following the recording of each pulse. In order to provide high speed playback or readout operations, a continuous drive mechanism is provided. This drive mechanism comprises a clutch magnet or solenoid 510 which moves a clutching idler into a position interposed between a driving roller and a pinch roller and capstan type of drive arrangement which directly drives the magnetic tape. In this manner, during playback operations, the magnetic tape in the trunk recorder 500 is rapidly advanced to produce mark and space impulses which are transmitted through the trunk circuit and the playback control circuit 460 to the recording facilities 410. A pair of contacts 511 in the energizing circuit for the magnet 530 are controlled by the clutch magnet 510 to prevent step-by-step operation of the magnetic tape during continuous drive operations.

In order to provide means for returning the magnetic tape in the trunk recorder 500 to its effective beginning or home position prior to recording and reproducing operatrons and in order to provide an alarm indication when the magnetic tape in the trunk recorder 500 is filled with items of information, a pair of tape controlled contacts 501 are provided which cooperate with three spaced perforations or conductive portions on the surface of the magnetic tape so as to define the effective beginning and end thereof. As disclosed in the above identified Gleason application, the tape contact structure may comprise portions carried on the surface of'the tape which selectively bridge contact fingers held in engagement with one surface of the magnetic tape. Alternatively, the tape contact arrangement may comprise a grounded roller and a contact brush between which the magnetic tape is interposed so that the brush and roller arrangement sense spaced perforations in themagnetic tape. A

9 OPERATION OF THE TRUNK CIRCUIT TO RE- CORD INFORMATION IN THE TRUNK RE- CORDER 500 During recording operations, the trunk circuit, under the control of dial impulses supplied from the calling subscriber and answering supervisory signals received from the calling subscriber, selectively controls the recording of items of information pertaining to a toll call on the magnetic tape of the trunk recorder 500. At the termination of the recording operation, an end-of-call code is recorded on the magnetic tape of the trunk recorder 50%), and a stepping switch and a pulsing source cooperate to advance the magnetic tape a predetermined distance following the last of the recorded items of information pertaining to the preceding toll call.

Referring now more specifically to the drawings, as described above, in response to the dialing of an access digit, the calling loop circuit is extended from the calling substation A through the line circuit 100, the finder Hi2, and the selector 104 to the trunk circuit shown in FIGS. 2 to 5, inclusive. This extension of the switch train to the trunk circuit completes the calling loop circuit through the input windings of a repeater coil 32%) and the upper and lower windings of a calling bridge relay SCB to ground through a pair of normally closed contactsi 3TS1 and to grounded battery. The completion of this circuit operates the calling bridge relay SCB to open a pair of contacts 3CB1 and to close a plurality of contacts ZCBZ, 3CB1, and 3CB2. The closure of the contacts 3CB1 and 3CB2 and the opening of the contacts ZCBl serve no useful function at this time. However, the closure of the contacts ZCBZ completes an obvious operating circuit for a release delay relay 2RD so that this relay operates to open a plurality of contacts 2RD1 and 4RD1 and to close a plurality of contacts 2RD2, 2RD3, 3RD1, SRDZ, and 3RD3.

The closure of the contacts 3RD1 applies ground to the sleeve lead of the extended switch train, thereby to hold the switch train operated and to indicate that the trunk circuit is busy. The opening of the contacts 4RD1 further opens an interrupted path for initiating an emergency playback operation of the trunk circuit by the playback control circuit 400. The closure of the contacts 3RD2 interconnects a timer motor 360 to a terminal 361 which is provided with a suitable energizing voltage, thereby to condition the timing means individual to the trunk circuit for operation. The closure of the contacts 3RD3 completes a circuit including the contacts 3SHS3, 3NI2, SCBI, r 3PT1, 3SHS4, 3RD3, and 3PT2 or 3CB2 for placing the right hand operating winding of the differential supervisory relay 38R across the outgoing tip and ring conductors of the trunk circuit. Further, the closure of the contacts 2RD2 energizes the left hand winding of the relay 35R, but the supervisory relay 35R is not operated at this time. The closure of the contacts 2RD3 prepares an operating circuit for a mark pulse relay 3MK and a motor magnet SDC of a stepping switch DC, and the opening of the contacts 2RD1 performs no useful function at this time.

The closure of the contacts ZRDZ also provides a source of main holding ground for the trunk circuit and completes an obvious operating circuit for a release delay slave relay ZRDS which operates to open a plurality of contacts ZRDSI, 3RDS1, SRDSZ, 3RDS3, and 4RDS2 and to close a plurality of contacts 2RDS2, 3RDS4, and 4RDS1. The closure of the contacts 4RDS1 grounds a conductor 403 to prevent seizure of the trunk circuit during a data recording operation, and the concurrent opening of the contacts -RDSZ performs no useful function at this time. The opening of the contacts 3RDS2 further interrupts one open circuit for supplying ground to the trunk sleeve terminal or conductor, ground remaining thereon at the closed contacts SRDT. The

opening of the contacts 2RDS1 interrupts a point at an open operating circuit for a diiferential end-of-call relay 2EC, and the closure of the contacts 2RDS2 prepares an operating circuit for a space relay 281 The open ing of the contacts SRDSI opens a shunt including a resistor 351 and a condenser 352 which is across the repeater coil 326. The resistor 351 has a value approximating that of the proper termination resistance for the trunk circuit looking into the trunk circuit from the remote switching equipment 300. The opening of the contacts 3RDS3 interrupts an additional point in an open operating circuit for a reset magnet SDCZ of the stepping switch DC.

The concurrent closure of the contacts 3RDS4 completes an obvious operating circuit for a slow-to-release third release delay relay BRDT so that this relay operates to close a plurality of contacts ZRDTI, 2RDT3, 2RDT4, and SRDTI and to open a plurality of contacts ZRDTZ, '4RDT1, and dRDTZ. The closure of the contacts ZRDTT prepares an operating circuit for the end-of-call relay ZEC, and the opening of the contacts ZRDTZ removes ground from a circuit extending through a plurality of closed contacts ZHMZ, ZCSl, and ZBYl and a normally closed switch 235 to a terminal 236 which is connected to a common supervisory control. The removal of ground from this terminal indicates that the trunk circuit is in a busy condition. The normally closed switch 235 is opened by the removal of the trunk recorder 500 to provide an indication that the trunk circuit is busy. The closure of the contacts ZRDTS prepares an operating circuit for the space relay ZSP, and the closure of the contacts 2RDT4 prepares another portion of the operating circuit for the mark relay SMK and the motor magnet 313C of the stepping switch DC. The closure of the contacts 3RDT1 provides an additional source of holding ground for the sleeve lead of the extended switch train, which ground is interrupted at the open contacts 3RDS2. The opening of the contacts 4RDT1 interrupts a point in an operating circuit for a home relay 4HM, thereby to prevent the operation of this relay during a data recording operation. The opening of the contacts 4RDTZ performs no useful function at this time.

The trunk circuit, in response to the seizure thereof, has operated the calling bridge relay 3GB and the release delay relays ZRD, ZRDS, and 3RDT to prepare pulsing paths for the space relay ZSP, the mark relay 3MK, and the motor magnet of the stepping switch 3DC to provide holding ground for the extended switch train and to provide busy ground to prevent additional attempted seizure of the trunk circuit by the circuit 4% or the telephone switching means. The trunk circuit is now conditioned to receive the first dialed information from the substation A which simultaneously operates the stepping switch DC and is recorded in the trunk recorder 5% but which is not repeated over the outgoing lines of the trunk circuit to the remote switching equipment 300.

The first item of information which is dialed by the calling subscriber at the station A following the seizure of the trunk circuit is a party digit which, as explained above, is of arbitrary value for calls placed from private lines, forms the units digit of the directory number for calling substations on terminal per line multiparty lines, and is utilized to selectively position the stepping switch DC to provide information for subsequently controlling the operation of the party matrix switching circuit 690 if the calling substation A is located on a terminal per station multiparty line. Accordingly, when the calling loop circuit extending to the trunk circuit is first interrupted incident to trans-mission of the first impulse of the dialed party digit, the calling bridge relay 3GB releases to close the contacts 2CB1 and to open the contacts ZCBZ, 3CB1, and SCBZ. The operations of the contacts 3CB1 and 3CB2 produce no useful function inasmuch as these contacts are shunted by the closed contacts 3PT1 and 3PT2. The opening of the contacts 2CB2 interrupts the above described operating circuit for the release delay relay 2RD, but this relay is slowto-release and does not release at this time. a The closure of the contacts 2CB1 applies ground through a circuit including the closed contacts 2SRS2, 2LD3, 2RD3, 2RDT4, 2IC5, 2PU4, and 3SD1 to be applied to the operating winding of the mark relay SMK, thereby operating this relay to close two pairs of contacts 4MK1 and 5MK1. The closure of the contacts 4MK1 forwards ground over a circuit including the closed contacts 4MKS1, 4MK1, 4CS13 to be applied to the operating winding of the mark pulse head 52-9, the other side of which is connected to grounded battery through a pair of normally closed contacts 4CS11. The completion of this circuit energizes the mark pulse head 529 to record a mark or information pulse on the mark pulse channel of the magnetic tape in the trunk recorder 5430 representing the first pulse of the dialed party digit. The closure of the contacts SMKI completes an obvious operating circuit for a second mark pulse relay SMKS which operates to open the contacts 4MKS1 and to close a pair of contacts 4MKS2. The opening of the contacts 4MKS1 interrupts the above described circuit for energizing the mark pulse head 520, thereby terminating the recording of the first mark pulse in the trunk recorder 500. The concurrent closure of the contacts -MKSZ completes an operating circuit for the ratchet magnet 530 extending from ground through the closed contacts 4MKS2, 5PA1, and 563, and the winding of the magnet 530 to grounded battery through a pair of contacts 511 controlled by the clutch magnet 510. The energization of the magnet 530 conditions the step-by-step driving mechanism in the trunk recorder 5% for advancing the magnetic tape a single step following the recording of the mark pulse thereon.

Referring to the above described circuit for operating the mark relay 3MK, the ground extended to the operating winding thereof in response to closing the contacts ZCBI is also extended through a plurality of closed contacts 3EC2 and 3PT4 to energize the motor magnet 3DC of the stepping switch DC so that a plurality of wipers 2DC1, 2DC2, 2DC3, and 2DC4 are advanced, the switch DC being of the direct acting type. In moving to the first stepping position in the bank of contacts adjacent thereto, the wiper 2DC1 prepares an operating path for a party one relay 2ON, which is one of a group of four party digit register relays including a group of other register relays 2T0, ZTR, and ZSTT. However, the operating circuit for the party one relay 2ON is not completed at this time inasmuch as ground is not supplied to any of the wipers 2DC1, 2DC2,or ZDCS. Thus the stepping switch DC is advanced a single step in synchronism with the recording of a single mark pulse on the magnetic tape in the trunk recorder 5%!) in response to the transmission of the first impulse of the dialed party digit.

The operation of the motor magnet 3DC also opens a pair of interrupter contacts 2DC5, but this produces "no useful function at this time. In advancing, the wipers ZDCl-ZDC- close a plurality of off-normal contacts 3DC1 and 3DC2. The closure of the contacts 3DC1 prepares an operating circuit for the reset or release magnet 3DCZ, and the closure of the contacts 3DC2 prepares an additional circuit for applying ground to the sleeve termi nal of the trunk circuit.

Referring back to the closure of the contacts SMKl in response to the operation of the mark relay 3MK, the ground provided thereby is extended through a plurality of closed contacts SECI and 5LD1 to complete an obvious operating circuit for a slow-to-release shunt relay SSH which, in operating, opens a plurality of contacts 281-11 ing the resistance in the pulsing circuit for thecalling bridge relay SCB. The opening of the contacts 3SH2 interrupts an additional point in the circuitfor applying ground to the wipers 2DC1, 2DC2, and 2DC3 of the stepping switch DC, and the concurrent closure of the contacts 3SH3 prepares an operating circuit for the motor magnet 3DC of the switch DC. The opening of the contacts 2SH1 interrupts a point in an operating circuit for the space relay 281.

The closure of the contacts SSHI completes an obvious operating circuit for a shunt slave relay SSHS which, in operating, closes a plurality of contacts ZSHSI, 2SHS2, SSHSI, 3SHS2, and 381- and opens a plurality of contacts 3SHS3, 3SHS4, and 3SHS6. The closure of the contacts 2SHS1 prepares a circuit for applying ground to the wipers ZDCl, 2DC2, and 2DC3 of the stepping switch DC, which circuit is interrupted at the open contacts 3SH2. The closure of the contacts ZSHSZ prepares a portion of an operating circuit for the 'space relay 2SP, which circuit is interrupted at the open contacts 281-11. The closure of the contacts 3SHS1 applies a shunt around one of the operating windings of the supervisory relay 35R, and the opening of the contacts 3SHS3 and 331-184 disconnects this winding of the supervisory relay from the pulsing paths extending to the conductors of the trunk circuit. The closure of the contacts 3SHS2 connects grounded battery to one of the leads of the trunk circuit through a circuit including the closed contacts 3NI2 and 3PT1, and the concurrent closure of the contacts 3SHSS connects ground to the other of the conductors of the trunk circuit through a circuit including the closed contacts SRDS and 3PT2. The opening of the contacts 3SHS6 interrupts a point in an operating circuit for the release magnet 3DCZ. At the end of the first open circuit interval representing the first pulse or the dialed party digit, the calling bridge relay 3GB again operates to close and open the contacts controlled thereby so that the contacts 3CB1 and 3CB2 connected in the signaling path of the trunk circuit are again closed, but the closure thereof has no effect due to the closed contacts 3PT1 and 3PT2. The closure of the contacts 2CB2 again completes the operating circuit for the slow-to-release release delay relay 2RD which is maintained operated during the release interval of the calling bridge relay 3GB. The opening of the contacts 2CB1, however, interrupts the above described opening circuit for both the motor magnet 3DC and the mark relay 3MK, thus permitting the magnet 3DC to release in preparation for the next operation thereof. The release of the mark relay SMK opens the contacts fiMKl and SMKI. The opening of the contacts 4MK1 interrupts, at an additional point, the previously interrupted circuit for energizing the mark pulse head 520, and the opening of the contacts SMKI interrupts the operating circuit for both the shunt relay SSH and the second mark pulse relay SMKS. The shunt relay SSH, however, is slow-to-release and does not release at this time.

However, the second mark pulse relay SMKS does release to close the contacts 4MKS1 and to open the contacts 4MKS2. The closure of the contacts 4MKS1 prepares the above described pulsing path for the mark pulse head 52! and the concurrent opening of the contacts 4MKS2 interrupts the above described operating circuit for the drive magnet 530, thereby permitting this magnet to release and to advance the magnetic tape in the trunk recorder 500 a single step. According, at the end of the first pulse of the dialed party digit, the stepping switch DC has been advanced a single step, a single mark pulse has been recorded on the magnetic tape in the trunk recorder 500, and this magnetic tape has been advanced a single step, the first pulsetransmitted to the trunk circuit further causing the operation of the shunt relay SSH and the shunt slave relay 'SSHS.

During the receipt of subsequent impulses in the series of impulses representing the value of the dialed party digit, the trunk circuit operates, as described above, to record additional mark puiscs on the mark pulse channel of the tape in the trunk recorder G0 and to advance this tape a single step at the termination of the recording of each of these pulses. Further, the stepping switch DC is advanced a single step in response to each impulse received by the trunk circuit from the extended switch train. Assuming that the calling substation A is located on a terminal per station multiparty line and is assigned the tenth position thereon, the assigned party digit is 0 and, accordingly, a series of ten open circuit intervals in the calling loop circuit is provided so that the calling bridge relay 30B operates and releases ten successive times during which ten mark pulses are recorded on the magnetic tape in the trunk recorder 500, and this magnetic tape is advanced ten steps. Further, the wipers ZDCl, 2DC2, 2DC3, and 2DC4- of the stepping switch DC are advanced ten steps so that these wipers engage the last contacts in the contact banks associated therewith.

1n the interdigit interval following the dialing of the dialed party digit, the trunk circuit conditions the signai ing circuit therein for extending switch directing impulses over the output conductors of the trunk circuit to selectively operate the remote switching equipment 309 so as to establish a connection to the called substation B, produces the operation of one or more of the party digit register relays ZON, 2T0, ZTR, and 2STT in accordance with the Value of the dialed party digit, restores the stepping switch DC to its normal position, and records a control or space impulse on the magnetic tape of the trunk recorder 50% immediately following the group of mark pulses representing the value of the dialed party digit, thereby to separate the record of the dialed party digit on the magnetic tape from the record pertaining to the next dialed digit. More specifically, in the interdigit interval following the dialing of the party digit, the slow-to-release shunt relay SSH releases to close the contacts 2SH1 and 351-12 and to open the contacts 3SH1, 351-13, and 581-11. The opening of the contacts 381-13 again interrupts the partially prepared operating circuit for the motor magnet 3DC of the stepping switch DC. The opening of the contacts SSHl interrupts the operating circuit for the shunt slave relays SSHS, but this relay is rendered slow-to-release by a circuit including a resistor 521 and a condenser 522 in parallel with the operating winding of the relay SSHS, and, accordingly, the shunt slave relay SSHS does not release at this time. The opening of the contacts 3SH1 removes the shunt around the upper winding of the repeat coil 320, and the closure of the contacts ZSHI completes an operating circuit for the space relay 2SP extending from closed and grounded contacts 2RDT3 through the closed contacts 2SHS2, 251-11, 2PU6, and 2SD2 to the operating winding of the relay ZSP.

The operation of the relay ZSP closes a plurality of contacts 3SP1 and 4SP1. The closure of the contacts 4SP1 completes a series circuit including the closed contacts 4SPS1, 4SP1, 4CS17, the operating winding of the space pulse head 540, a pair of closed contacts 40815 and grounded battery. The completion of this circuit energizes the space pulse head 540 to record a space pulse on the space pulse channel of the magnetic tape in the trunk recorder 500 immediately following the last of the group of ten recorded pulses thereon representing the value of the dialed party digit. The closure of the contacts 3SP1 completes an obvious operating circuit for a second space relay 3SPS which, in operating, opens the contacts 4SPS1 and closes a pair of contacts 4SPS2. The opening of the contacts 4SPS1 interrupts the above described energizing circuit for the space head 540, thereby to terminate the recording of the space pulse, and the concurrent closure of the contacts 4SPS2 completes the energizing circuit described above for the drive magnet 530, thereby to condition the magnetic tape for being advanced a single step.

Referring back to the preceding release of the shunt relay SSH, the closure of the contacts 3SH2 in response to release of this relay completes an obvious circuit for extending ground through a plurality of closed contacts 2PT4 and 2SHS1 to the wipers *2DC1, ZDCZ, and 2DC3 which, as described above, are in engagement with the tenth contacts in the contact banks associated therewith, thus representing the value of the dialed party digit as being 10. The ground applied to the wipers 2DC1, 2DC2, and 21303 is simultaneously extended to the operating windings of the party two relay 2T0 through a normally closed pair of contacts 2TO2, to the operating winding of the party three relay ZTR through a pair of normally closed contacts 2TR2, and to the operating Winding of the parties six-ten relay ZSTT through a pair of normally closed contacts ZSTTZ, thereby causing the simultaneous operation of these three relays. The concurrent operation of these relays provides a manifestation or representation of the value of the dialed party digit 10.

The operation of the party two relay 2T0 closes a plurality of contacts ZTOl, 2-TO4, 2TO6, 2TO7, and 3TO1 and opens a plurality of contacts 2TO2, 2TO3, and 2TO5. The contacts ZTOl and 2TO2 form a makebefore-break contact arrangement so that the contacts 2TO1 complete a circuit extending to holding ground at the closed contacts ZRDZ through a pair of normally closed contacts 2IC1 prior to the opening of the con tacts ZTOZ to interrupt the above described operating circuit for the relay 2T0. The selective operation of the contacts 2 TO3 to 2TO6, inclusive, partially prepares a marking path to one of five conductors designated "1 or 6, 2 or 7, "3 or 8, 4 or 9, and 5 or 10 in FIG. 6 of the drawings, which conductors extend to the party matrix switching circuit 600. The closure of the contacts 2TO7 prepares an operating circuit for a party transfer relay ZPT, and the closure of the contacts 3TO1 prepares an operating circuit for the release magnet BDCZ of the stepping switch DC.

The operation of the party three relay 2TR closes a plurality of contacts ZTRI, 2TR4, 2TR5, and 3TR1, and opens a plurality of contacts 2TR2 and 2TR3. The contacts 2TR1 and 2TR2 form a make-before-break contact arrangement in which the closure of the contacts 2TR1 completes a holding circuit for the relay 2TR extending to ground through the closed contacts ZICI and 2RD2 prior to the opening of the contacts ZTRZ to interrupt the above described operating circuit for the relay ZTR. The opening of the contacts ZTRS interrupts the partially prepared path extending to the conductor designated 2 or 7 by the closure of the contacts 2TO4, and the concurrent closure of the contacts 2TR4 prepares a marking path extending through the closed contacts ZTOG'to the conductor designated 5 or 10, thus indicating that the value of the stored party digit is either 5 or 10 in accordance with the operated or released condition of the parties six-ten relay ZSTT. The closure of the contacts 2TR5 prepares a circuit in parallel with the closed contacts 2TO7 for operating the party transfer relay 2PT. The closure of the contacts 3TR1 provides a source of operating ground which is parallel to that provided by the closed contacts 3TO1 in the partially conditioned operating circuit for the release magnet 3DCZ.

The operation of the parties six-ten relay ZSTI' closes a plurality of contacts 2STT1 and 2STT4 and opens a plurality of contacts 2STT2 and 2STT3. The contacts 2STT1 and 2STT2 form a make-before-break contact arrangement so that the closure of the contacts ZSTTl completes a holding circuit extending to ground through the closed contacts 2101 and 2RD2 prior to the opening of the contacts 2STT2 to interrupt the above described operating circuit for the relay ZSTT. The opening of the contacts ZSTTS indicates that the value of the stored party dig-it is not in the range of the digits 1 to by opening an operating path for a one-to-five relay GOTF in the matrix 'switc-hing circuit 600, and the concurrent closure of the contacts 2STT4 prepares a circuit for operating an above five relay 6AF, thereby to indicate that one of the two digits represented by the selection of the conductor designated as 5 or is in the range above 5 or has the value of 10.

Although the operation of the party one relay 2ON has not been described in detail, this relay is operated by the stepping switch DC when the value of the stored party digit is 1, 4, 6, or 9 to actuate a plurality of contacts 2ON1, 2ON2, 2ON3, 2ON4, ZONE, 2ON6, and 3ON1 to perform substantially the same functions as the operation of the relays 2T0 and ZTR. Accordingly, the selective operation of one or more of the group of party digit register relays ZON, 2T0, 2TR, land ZSTT establishes partially prepared circuits extending to the party matrix switching circuit 600 in accordance with the value of the stored party digit on one of five conductors, each of which represents a digit equal to or less than 5 and a digit greater in value than 5. The relay ZSTT also prepares a circuit on one of two conductors extending to the switching circuit 600 in accordance with whether the registered digit has a value equal to or less than 5 or more than 5, thereby to prepare the switching circuit 600 for selecting a single control component or party matrix in accordance with the register value of the party digit. The relays ZON, 2T0, and ZTR also prepare operating paths for the reset magnet 3DCZ and the party transfer relay 2PT.

Following a suitable time interval sufficient to cover the above described operations, the shunt slave relay SSHS, the operating circuit for which was interrupted by the release of the shunt relay SSHS, releases to open the Contacts ZSHSl, 2SHS2, SSHSI, 3SHS2, and 3SHS5 and to close the plurality of contacts 3SHS3, 331-184, and 3SHS6. The contacts 3SH S1 remove the shunt around the Winding of the supervisory relay 3 8R, while the closure of the contacts SSHSS and 3SHS4 interconnects this winding of the relay 38R with the line conductors of 'the trunk circuit. The opening of the contacts 381-185 and 381-182 disconnects ground and grounded battery from the line conductors of the trunk circuit. The opening of the contacts ZSHSI interrupts the above described circuit for supplying ground to the wipers 2DC1, 2DC2, and 2DC3'of the stepping switch DC.

The opening of the contacts 2SHS2 interrupts the above described operating circuit for the space relay. ZSP so that this'r'elay releases to open the contacts 3SP1 and 4SP1. The opening of the contacts 4SP1 interrupt-s at an additional point the above described operating circuit for the space pulse head 540, and the openingof the contacts 3SP1 interrupts the operating circuit for the second space relay 3SPS so that this relay releases to close the contacts 4SPS1 and to open the contacts 4SPS2.. The closure of the cont-acts 4SPS1 prepares the above described operating circuit for the space pulse head 540, and the opening of the contacts 4SPS2 interrupts the above described operat- Referring back to the'above described release of the shunt slave relay SSHS, the closure of the contacts 3SHS6 completes an operating circuit for the release magnet 3DCZ of the stepping switch DC extending from ground at either of the closed contacts 3TO1 or 3TR1 through the closed contacts 3SHS6, 3PT5, and the closed oifnormal contacts 3DC1 of the stepping switch DC. In

response to energization of the magnet 3DCZ, the wipers ZDCI, 2DC2, 2DC3, and 2 DC4 are mechanically returned to their normal position illustrated in FIG. 2 of the drawings. 'The energization of the magnet 3DCZ also closes a pair of release magnet springs 4DCZ1 to apply g rouhd to a terminal 435 through a parallel combination of a resistor 407 and an alarm lamp 406. The continuous maintenance of ground on the terminal 405 provides delayed illumination of the lamp 406 to pro vide a visible indication in the event that the release magnet 3DCZ is not released within a selected period of time.

In restoring the wipers 2DC1, 2DC2, 2DC3, and 2DC4 of the stepping switch DC to their normal home positions, the off-normal contacts 3DCZ are opened, which perform no useful function, and the contacts 3DC1 are opened to release the release magnet 3DCZ so as to open the contacts 4DCZ1. The restoration of the wipers 2DC1-2DC4 to their home positions also completes an operating circuit for the party transfer relay ZPT extending from closed and grounded contacts 3SH2 over the wiper 2DC4 and through the closed contacts 2TO7 and 2TR5 in parallel and a pair of normally closed contacts 2PT1. The completion of this circuit operates the party transfer relay ZPT to indicate the completion of the operations of the trunk circuit in which the party digit is stored in the party digit register relays ZON, 2T0, ZTR, and 2STT and in which the value of this digit is stored in the trunk recorder 500. In operating, the party transfer relay ZPT conditions the trunk circuit to repeat the next dialed digits from the switch train over the trunk conductors to the remote switching equipment 300, thereby to establish a connection to the calledsubstation B. The party transfer relay further conditions the stepping switch DC to count the number of dialed digits to prevent the transmission of superfluous digits to the trunk recorder 500 and over the trunk circuit to the remote switching equipment 300.

The operation of the party transfer relay closes a plurality of contacts ZPTZ, 2PT3, 3PT3, and 5PT1 and opens a plurality of contacts 2PT1, ZPT 4, 3PT1, 3PT2, 3PT4, and 3PT5. The contacts 2PT1 and 2PT2 form a makebefore-break contact arrangement so that the closure of the contacts 2PT2 completes a holding circuit to the closed and grounded contacts ZRDZ prior to the opening of the contacts 2PT1 to interrupt the operating circuit for the party transfer relay 2PT. The opening of the contacts 2PT4 interrupts, at an additional point, the above described circuit for applying ground to the wipers 2DC1, 2DC2, and 2DC3. The closure of the contacts 2PT3 prepares an operating circuit for a last digit relay 2LD extending to the seventh contact in the contact bank engaged by the Wiper 2DC4, thereby preparing the last digit relay 2LD for operation following the transmission of seven digits over the extended switch train to the trunk circuit. The opening of the contacts 3'PT1 and 3PT2 conditions the signaling circuit in the trunk circuit for operation by the contacts 3CB1 and 3CB2 controlled by the calling bridge relay 3GB so that dial pulses transmitted to the trunk circuit are repeated over the trunk conductors to the remote switching equipment 300. The closure of the contacts 3PT3 prepares an operating circuit for the motor magnet 3DC of the stepping switch DC so that this switch is enabled to count the digits transmitted to the trunk circuit from the calling substation A, and the concurrent opening of the contacts 3PT4 interrupts the above described operating circuit for the motor magnet 3DC. The opening of the contacts 3PT5 interrupts, at an additional point, the operating circuit for the reset magnet 3DCZ The closure of the contacts 5PT1 prepares an operating circuit for a clock-calendar relay SCC. The trunk circuit is now conditioned to receive the series. of pulses representing the directory number of the called subscriber B.

Assuming that a conventional 21-5 numbering scheme is utilized, the calling bridge relay 3GB is released in response to the first calling loop circuit interruption produced by dialing the first digit identifying the called substation B, thereby to close the contacts 2CB1 and to open the contacts 2CB2, 3CB1, and 3CB2. The open- 17 ing of the contacts 3CB1 and 3CB2 produces no useful function at this time, and the opening of the contacts 2CB2 again interrupts the operating circuit for the release delay relay 2RD which does not release at this time due to the slow-to-release characteristic thereof. The closure of the contacts 2CB1 sequentially operates the mark relay SMK, the second mark relay SMKS, the shunt relay SSH, and the shunt slave relay SSHS, as described above, so as to momentarily energize the mark pulse head 520 to record a single mark pulse on the magnetic tape of the trunk recorder 50%) and to energize the drive magnet 530 to condition the magnetic tape for a single step of advancement.

The sequential operation of the shunt relay SSH and the shunt slave relay SSHS produces the same functions described above with the following exception. The closure of the contacts 3SHS2 and 3SHS5 extends grounded battery and ground to the now open contacts 3CB1 and 3CB2 controlled by the calling bridge relay 3CB in prepmation for providing ground and battery for pulsing the conductors of the trunk circuit extending to the remote switching equipment 300. The closure of the contacts 3SH3 completes the energizing circuit for the motor magnet 3DC so that the contacts 2DC5 are opened and the wipers 2DC1, 2DC2, 2DC3, and 2DC4 are advanced to the first contacts in the contact bank associated therewith, thereby representing the dialing of the first digit of the cfled subscriber designation. The opening of the contacts 2DC5 produces no useful function at this time. In advancing the switch DC off-normal, the oif-normal contacts 3DC1 and 3DC2 are closed. The closure of the contacts 3DC1 prepares an operating circuit for the release magnet SDCZ, which is now interrupted at the open contacts 3PT5, and the closure of the contacts 3DC2 again provides a source of holding ground for the sleeve lead of the extended connection, which ground is ineffective due to the open contacts 3RDS2.

When the calling bridge relay SCB is again operated in response to reclosure of the calling loop circuit at the calling substation A, the contacts 2CB2, 3CB1, and 3CB2 are closed, and the contacts 2CB1 are opened. The opening of the contacts 2CB1 releases the mark relay 3MK and the second mark relay SMKS to permit the magnet 530 to release and thus advance the magnetic tape in the recorder 500 a single step following the recording of the first mark pulse representing the value of the first dialed digit of the called subscriber designation. The closure of the contacts 2CB2 again completes the operating circuit for the release delay relay 2RD. The closure of the contacts 3CB1 and 3CB2 applies grounded battery and ground, respectively, to the conductors of the trunk circuit extending to the remote switching equipment 300, thereby to provide a first switch directing pulse to control the switching equipment 300 in establishing a connection to the called substation B.

When the calling bridge relay 3GB is next released in response to a line interruption, the contacts ZCBll are again closed to sequentially operate the mark relay 3MK and the second mark relay SMKS to record a second pulse on the magnetic tape in the trunk recorder 500 and to energize the drive magnet 530 in preparation for advanc ing the magnetic tape a single step. Further, in operating, the contacts 3GB! and 3CB2 are again opened to remove grounded battery and ground, respectively, from the conductors of the trunk circuit to terminate the first pulse supplied to the remote switching equipment 300. This intermittent operation and release of the calling bridge relay 3CB continues until such time as the series or group of pulses representing the value of the first dialed digit has been transmitted to the remote switching equipment 300 and also recorded on the magnetic tape in the trunk recorder 500.

In the interdigit interval following the completion of the transmission of this group of impulses, the shunt relay SSH releases after its slow-to-release interval to open the contacts 3SH3 so as to interrupt the above described operating circuit for the motor magnet 3DC of the stepping switch DC. The switch, in releasing, again closes the interrupter contacts ZDCS which produces no useful function at this time. Further, as described above, the sequential release of the shunt relay SSH and the shunt slave relay SSHS in closing the contacts 2SH1 and in opening the contacts ZSHSZ momentarily energizes the space relay 28F and the second space relay 3SPS so that a single space pulse is recorded on the magnetic tape of the trunk recorder 500 immediately following the first digit in the designation of the called subscriber B.

In this manner, the calling bridge relay 3CB, the first and second mark relays 3MK and SMKS, the first and second space relays ZSP and 3SPS, the shunt relay SSH, the shunt slave relay SSHS, and the motor magnet SDC operate during the next six digits transmitted over the extended switch train to the trunk circuit to record the values of these digits on the magnetic tape in the trunk recorder 50% in the form of groups of mark pulses including pulses equal in number to the value of the digit. The dial pulses are further repeated over the trunk circuit to the remote switching equipment 301 to control the establishment of a switch train to the called subscriber B in the remote area. Concurrently therewith, the shunt relay SSH sequentially advances the stepping switch DC so that the wipers ZDCl, 2DC2, 2DC3, and 2DC4 thereof are advanced over the contacts engaged thereby so that, at the completion of the transmission of this sixth additional digit, or the seventh digit, the wiper ZDC4, together with the other wipers in the switch DC, are positioned in engagement with the seventh contact in the contact bank associated therewith. In this position, the wiper 2DC4 is connected to the operating winding of the last digit relay 2LD through a circuit including the closed pairs of contacts 2PT3 and 2LD1. The selective operation of the last digit relay informs the trunk circuit that the proper complement of digits necessary for extending a connection to a remote subscriber, such as the called substation E, has been both transmitted and recorded in the trunk recorder 59%, and, accordingly, the last digit relay provides means for preventing the storing of additional digits in the trunk recorder 504 and for likewise preventing the transmission of additional information over the trunk circuit to the remote switching equipment 300.

More specifically, in the interdigit interval following the dialing of the last of the seven digits dialed to obtain access to the called substation B, the shunt relay SSH releases, as described above, and in doing so closes the contacts 3SH2 to complete an operating circuit for the last digit relay ZLD extending over the wiper 2DC4 through the seventh contact in the bank associated therewith and the closed contacts 2PT3 and 2LD1. Concurrently therewith, the closure of the contacts 251-11 completes the above described operating circuit extending to the space relay 2S1 so that this relay and the second space relay 3SPS sequentially operate to record a space pulse on the tape in the trunk recorder 50% immediately following the seventh dialed digit of the called subsoriber designation and to energize the drive magnet 530 to condition the magnetic tape for a single step of advancement.

In operating, the last digit relay closes a plurality of contacts 2LD2, 3LD1, and 3LD2 and opens a plurality of contacts 2LDl, 2LD3, and 5LD1. The contacts ZLDl and 2LD2 form a make-before-break contact arrangement in which the closure of the contacts 2LD2 completes a holding circuit for the relay 2LD extending to the closed and grounded contacts ZRDZ prior to the opening of the contacts 2LD1 to interrupt the above described operating circuit for this relay. The opening of the contacts 2LD3 interrupts the above described pulsing path for the mark relay 3MK and thus prevents further pulsing of the calling bridge relay 3CB from controlling the recording of information in the trunk recorder 500.

19' The closure of the contacts 3LD1 and 3LD2 provides a shunt around the contacts, 3CB1 and 3CB2 controlled by the calling bridge relay 3GB and thus prevents the transmission of additional pulse information to the remote switching equipment 300. The opening of the contacts 5LD1 interrupts the above described operating circuit for the shunt relay SSH so that further operation of the second mark pulse relay SMKS incident to recording clock and calendar information and other items of information, such as the designation of the calling substation A, does not produce an accompanying operation of the shunt relay SSH and the shunt slave relay SSHS.

The next item of information received by the trunk circuit is supplied from the remote area over the trunk circuit and comprses either reverse battery answering supervisory signals or a reverse battery flashing indicating a busy condition. The supervisory relay 35R, which is connected across the conductors from the trunk circuit through the closed contacts 351-153 and 351-154 and 3LD1 and 3LD2 responds to these signals either to prevent the recording of additional information, in the event that a busy tone is received, or to provide an indication that the necessary additional items of information pertaining to the toll call are to be recorded, in the event that answering reverse battery supervision is received.

Assuming that busy signals are recevied by the trunk circuit indicating that the connection cannot be completed to the called subscriber B, the supervisory relay 33R is operated to close a pair of contacts 3SR1 which completes an obvious operating circuit for a second supervisory relay 3SRS extending to the closed and grounded contacts 2RD2. The operation of the second supervisory relay SSRS closes a pair of contacts 2SRS1 and opens a pair of contacts ZSRSZ. The opening of the contacts ZSRSZ interrupts an additional point in the above described pulsing circuit extending to the mark relay SMK which is controlled by the contacts 2CB1. The closure of the contacts 2SRS1 forwards ground from the closed contacts 2RD2 to the operating winding of a timer clutch 230 forming a portion of the timing mechanism whose drive motor 360 was previously energized by the closure of the contacts 3RD2. This timing mechanism, which is individual to the trunk circuit, preferably is of the type disclosed in the copending application of Armistead Wharton, Serial No. 497,760, filed March 29, 1955, which application is assigned to the same assignee as the present application. In general, the timing mechanism disclosed therein comprises an electric clock motor 360 for driving a mechanical cam arrangement through an intervening clutch 230 so that the cam arrangement is adapted to close a pair of contacts 231 to provide a control pulse or signal at the end of a relatively short interval of time, such as an interval of from one to two seconds, during which a busy test is performed by the trunk circuit to determine the idle or busy condition of the line extending to the called subscriber B. The timing mechanism also includes a pair of normally open contacts 232 which are initially closed to provide a first duration impulse approximately sixty-five to sixty-seven seconds following the energization of the clutch 230 and which thereafter are operated to provide duration impulses at one minute intervals, thereby to provide a means for recording information pertaining to the length of the toll call. This mechanism is such that, in response to termination of the energization of the timer clutch 230, the cam mechanism is immediately returned to its normal starting position so that, upon reenergization of the clutch 230, the contacts 231 and 232 are again closed in the sequence described above.

' Therefore, when the timer clutch 230 is energized by the closure of the contacts ZSRSI in response to operating the second supervisory relay 3SRS, the timing mecha nism is placed in operation so that, after an interval of beween one to two seconds, the contacts 231 are closed. However, if, as assumed above, a sixty cycle busy flashing signal is being received by the trunk circuit, the supervisory relay 38R is released to releasethe second super-' visory relay 3SRS before the completion of the timing out of the control timing interval provided by the contacts 231. The release of the second supervisory relay 3SRS opens the contacts 2SRS1 to terminate energization of the timer clutch 230 so that the cam arrangement forming a portion of this timer is immediately restored to a normal condition. Thereafter, the supervisory relays 38R and 3SRS and the timer clutch 230 are intermittently operated and released in accordance with the busy flashing supplied to the supervisory relay 3-SR from the remote switching equipment 300.

This intermittent operation continues until such time as the subscriber at the calling substation A, in response to the receipt of busy tone, opens the calling loop circuit to release the calling bridge relay 3GB, the party transfer relay ZPT, the last digit relay ZLD, and the release delay relays 2RD, ZRDS, and 3RDT and to restorethe stepping switch DC to its normal position. Incident to these operations and as described in detail hereinafter, the stepping switch DC cooperates with a pulse assist relay ZPA and an end-of-call relay ZEC to provide a measured or counted number of steps of advancement of the magnetic tape in the trunk recorder 500 immediately following the recording of an end-of-call code representing the end of the items of information pertaining to the incomplete call. The measured run-off of the magnetic tape provides a space between the items of information pertaining to this incomplete call and those pertaining to the next call placed through the trunk circuit.

However, assuming that steady reverse battery answering supervisory signals are received by the trunk circuit from the remote switching equipment 300, the supervisory relay 35R and the second supervisory relay 3SRS are operated, as described above, to close the contacts SSRI, 2SRS1, and to open the contacts 2SRS2. The closure of the contacts ZS'RSl energizes the timer clutch 230 so that the cam arrangement is advanced under the control of the timer motor 230 to close the contacts 231 after an inter val of between one to two seconds. The closure of the contacts 231 completes an obvious operating circuit for a third supervisory relay Z'SRT extending to the closed and grounded contacts 2RD2 through a pair of closed contacts 2SRT3. The operation of the third supervisory relay 25R indicates the satisfactory completion of the busy test and thus initiates the recording of the remainder of the necesary items of information pertaining to this toll call.

More specifically, the operation of the third supervisory relay 2SKT closes a plurality of contacts 2SRT1, ZSRTZ, and 2SRT4 and opens the contacts ZSRTS. The contacts ZSRTS and 2SRT4 form a make-before-break contact arrangement so that the closure of the contacts 2'SRT4 completes a holding circuit extending to the closed and grounded contacts 2RD2 prior to the opening of the contacts 2SRT3 to interrupt the above described operat ing circuit for'the relay 2SRT. The closure of the contacts 2SRT2 provides an alternative path for energizing the timer clutch 230 which is shunted around the contacts 2SRS1 so that, in the event that the connection is released or the line is flashed to intermittently operate and release the relays 38R and SS-RS, the timer clutch 230 cannot be released to res-tore the timer to a normal condition. In this manner, the timing of the call is con tinuously maintained following the expiration of the one to two second interval provided prior to the closure of the contacts 231 and the consequent operation of the third supervisory relay ZSRT.

To initiate the recording of the next date and time item of information in the trunk recorder 500, the closure of the contacts 2SRT1 completes an operating circuit for a pickup relay 2PU extending through a plurality of closed contacts ZPUZ, 2IC3, 2CC1, and 2SRT1 to the clockcalendar circuit 220. As described in detail in the above identified copending Clement et a1. application, the clockcalendar circuit 220 supplies ground over the above..d@-

scribed circuit to operate the pickup relay ZPU, if the clock-calendar circuit 226 is idle at the time that the contacts ZSRTl are closed. The operation of the pickup relay ZPU closes a plurality of contacts 2PU1, 2PU3, ZPUS, 2PU'7, ZPUS, and SPUl and opens a plurality of contacts 2PU2, 2PU4, and 2PU6. The contacts ZPUl and ZPUZ form a make-before-break contact arrangement so that the closure of the contacts ZPUI completes a holding circuit for the pickup relay ZPU extending to the clock-calendar circuit 229 prior to the opening of the contacts ZPUZ to interrupt the above described operating circuit for this relay. The opening of the contacts 2PU4- interrupts an additional point in the above described pulsing path for the mark relay 3MK, and the concurrent closure of the contacts ZPUS connects the operating winding of the mark relay SMK to the clock-calendar circuit 22%) so that the mark relay 3MK is now controlled by ground pulses provided by the clock-calendar circuit 221}- in accordance with date and time information. The opening of the contacts 2PU6 interrupts the above described pulsing path for the space relay 28?, and the concurrent closure of the contacts ZPU7 connects the operating winding of this relay to the clock-calendar circuit 220 so that the space relay 28F and the second space relay ESP'S are conditioned for operation in accordance with pulses supplied by the circuit 229.

The closure of the contacts ZPUS provides an additional source of holding ground for the release delay relay 2RD to maintain this relay operated and, accordingly, the trunk circuit in an operative condition in the event that the connection is released during the interval that the clock-calendar circuit 22%; provides information to the trunk recorder A set forth above, following the completion of the timing of the interval determined by the contacts 231, the call is to be assessed to a subscriber, and, accordingly, additional holding ground means are provided for maintaining the trunk circuit in an operative condition to permit the recording of complete information pertaining to the toll call even though the connection is released by the subscriber.

The closure of the contacts SPUl completes a preliminary operating circuit for a clock-calendar relay SCC of the two step type so that this relay operates to close a pair of preliminary make contacts 5CC1 and to open a pair of preliminary break type contacts ZCCT. The closure of the contacts SCCT prepares a full operating circuit for the relay SCC, but this relay does not completely operate until the ground shunt around the right hand operating winding thereof is removed by the opening of the contacts SPUl. The opening of the contacts ZCCl prevents reoperation of the pickup relay ZPU following the completion of the transmission of the date and time information from the clock-calendar circuit 226 to the trunk recorder 50%.

Referring to the above described operation of the pickup relay ZPU, the closure of the contacts 2PU3 applies ground to the cloc -calendar circuit 228 to initiate a cycle of operation thereof during which a plurality of groups of mark pulses representing instant date and time are transmitted over the above described circuit to the operating winding of the mark relay 3MK, thereby to cause the recording of this information in the recorder 55%. The clock-calendar circuit 229 also provides a plurality of ground pulses for operating the space relay 2SP to record space pulses on the magnetic tape between adjacent groups of the mark pulses, as described above in conjunction with the recording of the dialed digits representing the designation of the called substation B. When all of the necessary items of information pertaining to date and time have been transmitted from the clock-calendar circuit 220, the pickup relay ZPU is released to cause the full operation of the clock-calendar relay SCC as an indication that all of the date and time information has been transmitted to the trunk recorder 500.

More specifically, in response to the completion of the transmission of the necessary information by the clockcalendar circuit 220 and in the manner described in detail in the above identified copending Clement et al. application, ground is removed from the conductor extending to the holding contacts ZPUI of the pickup relay ZPU so that this relay releases to open the contacts 2PU1, 2PU3, ZPUS, 2PU7, 2PU8, and SPUl and to close the contacts 2PU2, 2PU4, and 2PU6. The opening of the contacts ZPUS and 2PU7 and the closure of the contacts 2PU4 and 2PU6 interrupt the pulsing paths for the mark and space pulse relays 3MK and 28? previously extended to the clock-calendar circuit 220 and initiate the preparation of additional circuits extending to these relays. The opening of the contacts 2PU1 and the closure of the contacts ZPUZ interrupt the holding circuit for the pickup relay ZPU and reestablish the above described operating circuit for this relay, the operating circuit, however, being maintained interrupted at the open contacts 2CC1. The opening of the contacts 2PU3 removes start ground from the clockcalendar circuit 22%, and the opening of the contacts 2PU8- removes the source of holding ground from the release delay relay 2RD.

However, the opening of the contacts 5PU1 removes the ground shunt around the right hand operating winding of the two step clock-calendar relay 5CC so that this relay now fully operates to close a plurality of contacts 2CC2, SCCI, and *SCCZ. The closure of the contacts ZCCZ reestablishes the holding ground source for the release delay relay ZRD to maintain this relay operated in the event that the connection has previously been released, this relay normally being held operated by the closed contacts ZCBZ. The closure of the contact 3CCE provides marking ground on a conductor individual to the trunk circuit which extends to the banks of contacts of the switching devices associated with the identifier sender, such as the identifier sender 310, thereby to mark this trunk circuit as requiring the association of an identifier sender. The closure of the contacts 3CC2 extends start ground to a terminal 311 which is connected to an identifier sender allotter (not shown) which preferably is of the type disclosed in the above identified copending Clement et al. application. The application of start ground to the identifier sender allotter causes the allotter to actuate the switch in a preselected idler identifier sender, such as the sender 31%, to search for and seize the contact multiples individual to the calling trunk circuit. Accordingly, in response to the completion of the transmission of date and time information, as signified by the release of the pickup relay ZPU and the consequent full operation of the clockcalendar relay SCC, an automatic calling line identification operation is initiated.

To initiate the automatic calling line identification operation and as described in detail in the above identified copending Clement et al. application, the switching means indicated schematically in conjunction with the block diagram of the identifier sender 310 is placed in operation so that a plurality of wipers 316a, 310b, 3100, and 314M step over their associated contact banks with the wiper 310a searching for the marking ground provided at the closed contacts 3CC1. When the wiper 310a moves into engagement with the contacts grounded by the closed contacts 3CC1, in which position the other wipers 310b, 310a, and 310d likewise engage contact multiples individual to this trunk circuit, the identifier sender 310 forwards ground over the wiper 3190' to complete an obvious operating circuit for a start identification relay 38D.

The operation of the relay BSD closes a plurality of contacts ZSDl, 2SD3, 2SD4, 38132, 3SD3, 35134, 3SD6, and 3SD7 and opens a plurality of contacts ZSDZ, 3SD1, and SSDS. The contacts 3SD4 and 3SD5 form a makebefore-break contact arrangement so that the closure of the contacts SSDS completes a holding circuit for the relay 35D extending to the closed and grounded contacts 3CC1 prior to the opening of the contacts 3SD4 to inter- 23 rupt the above described operating circuit for the relay 38D. The opening of the contacts 3SD1 interrupts the above described operating circuits for the mark relay 3MK, and the concurrent closure of the contacts 3SD2 prepares an operating circuit for this relay extending over the wiper 31012 to the identifier sender 310 to condition the mark relay 3MK for subsequent operation by ground pulses applied to the wiper 31% from the identifier sender 310. The opening of the contacts 2SD2 interrupts the above described operating circuits for the space relay ESP, and the concurrent closure of the contacts 2SD3 interconnects the Winding of this relay with the wiper 313d to permit operation of the space relay ZSP in accordance with ground pulses applied to the wiper 310d by the identifier sender 310. The closure of the contacts 2SD1 provides an alternative path shunted around the closed contacts 2IC1 for supplying holding ground to the operated ones of the partly digit register relays ZON, 2T0, ZTR, and ZSTT. The closure of the contacts 3SD7 prepares an operating circuit for the no-identification relay 3N1. The closure of the contacts 2SD4 provides an additional source of holding ground for the release delay relay 2RD to maintain this relay operated in the event that the connection is released during the recording of calling line identification information.

The closure of the contacts 3SD6 completes an obvious operating circuit for an identify relay 31D extending to the ground provided on the wiper 310a so that this relay operates to close the plurality of contacts ZlDl, 2ID2, 2ID3, and 3ID1. The closure of the contacts '3ID1 provides an additional source of holding ground for the start identification relay 38D and for extension over the wiper 310a to the identifier sender 310.

The operation of the identify relay 31D supplies the identification potential for return over the HS lead of the extended switch train to selectively energize the identification matrix circuit 680 and also completes the paths prepared by the selective operation of the party digit register relays 2T0, ZTR, and ZSTT for operating the party matrix switching circuit 6% in accordance with the stored value of the dialed party digit. More specifically, the closure of the contacts 2ID2 completes the path extending through the previously closed contacts 2TR4- and 2TO6 to extend grounded battery to the 5 or '10 conductor in the party matrix switching circuit 609. The closure of the contacts 2ID1 extends ground through the closed contacts 2STT4 to complete the operating circuit for the above five relay GAF so that this relay operates to close a plurality of contacts 6AF1, 6AF2, 6AF3, 6AF4, and 6AF5. The closure of the contacts 6AF5 extends the grounded battery provided on the 5 or' 10 conductor to the conductor connected to the operating winding of a cut-through relay 61% associated with the party ten matrix 630 in accordance with the above described position of the calling substation A on the terminal per station multiparty line. The operation of the relay 610 interconnects the party ten matrix 630 with the plurality of common busses extending to the input of the identifier circuit 690, thereby to prepare the identifier circuit 690 for receiving digital information representing the directorynumber of the tenth party on the terminal per station multiparty line. If the registered party dial is assumed to be 5 rather than 10, the relay ZSTT remains released so that the closure of the contacts ZlDl' operates the one-to-five relay OTF to close a plurality of contacts 6OTF1-6OTF5 so that a party five matrix switch relay (not shown) is operated.

The closure of the contacts 2ID3 extends an identification potential from the power supply circuit 210 over the HS leadtof the extended switch train through the selector 134 and the finder M2 to the HS multiple of the calling line circuit 1%, thereby permitting this potential to be extended over the identification conductor 110 to the terminal 111. The terminal 111, in accordance with the above assumption that the calling substation A is located in the tenth position on a terminal per station multiparty line, is connected to the plurality of party matrices 610, 620, and 630 so that each of these individual party matrices is energized to provide digital information representing the directory numbers of all of the substations on the line terminating in the line circuit 160. However, the output of only the party ten matrix 630 is cut through to the input of the identifier circuit 690, as described above, so that these signals selectively operate the identifier circuit 6% in accordance with the four digits forming the directory number of the calling substation A. The output of the identifier circuit 690 is extended over a cable 691 to the input of the identifier sender 310 so that digit registering components in the sender 319 are operated in accordance with the values of the four digits forming the directory number of the calling substation A,

Referring back to the preceding operation of the start identification relay 38D, the closure of the contacts 3SD3 completes an operating circuit for an identification complete relay 31C extending from the closed and grounded contacts 3RDS4. Operation of the identification complete relay 31C opens a plurality of contacts 2IC1, 2103, 2IC5, and 5IC1 and closes a plurality of contacts 2102, 2101, and SICI. The closure of the contacts 3IC1 completes an obvious holding circuit for the slow-to-release identification complete relay 3IC. The closure of the contacts 2IC2 prepares an operating circuit for the space relay 281. The opening of the contacts 2IC1 interrupts the above described holding circuit for the operated party digit register relays 2T0, 2TR, and ZSTT, but this holding circuit is maintained through the closed contacts 2SD1.

' 3MK under the control of the timer contacts 232. The

opening of the contacts 2IC3 interrupts, at an additional point, the operating circuit for the pickup relay ZPU, thereby to prevent reoperation of this relay.

The opening of the contacts 5IC1 interrupts the above described operating circuit for the clock-calendar relay SCC, thereby to release this relay to close the contacts ZCCl and to open the contacts 2CC2, 3CC1, 3CC2, and 5CC1. The opening of the contacts 5CC1 interrupts, at an additional point, the operating circuit for the clock-calendar relay SCC. The closure of the contacts ZCCl prepares a portion of the operating circuit for the pickup relay 2PU, which circuit is interrupted at the open contacts 2IC3. The opening of the contacts ZCCZ removes a source of holding ground for the release delay relay 2RD, but this relay is maintained operated by the ground provided at the closed contacts ZCBZ and 2SD4. Since the identification complete relay 31C is operated and the clock-calendar relay SCC released in response to the completion of the association of the identifier sender 310 with the trunk circuit, the opening of the contacts 3CC2 removes start ground from the terminal 311 which is connected to the identifier sender allotter, thereby to restore the allotter to a normal condition. Further, the opening of the contacts 3CC1 removes marking ground from the wiper 310a and holding ground from the relay 3SD, but the closed contacts 3ID1 maintain ground on these circuits.

As described above, in response to the operation of the identify relay 31D, the party matrix switching circuit 600 is selectively operated in accordance with the paths prepared by the selective operation of the operated party digit register relays 2T0, ZTR, and ZSTT to render the party ten matrix 630 effective to supply signals to the identifier circuit 6%. The operation of the identify relay 31D further extends the identification potential over the HS lead to the extended switch train to the terminal 111 which is assumed to be connected in the party ten matrix 6336, thereby to energize the input of the identifier circuit 690 in accordance with signals representing the digits forming the directory number of the calling substation A on a terminal per station multiparty line. These signals are conducted over the output cable 691 to the identifier sender 310 to store these digits in the identifier sender 310. In the event that an adequate calling line identification is provided in the identifier sender 310, the sender 310 signals the trunk circuit that the transmission of the stored digits to the trunk recorder 59% may proceed. Alternatively, in the event that satisfactory identification information relating to the calling substation A has not been received by the sender 310, a signal is supplied to the trunk circuit representing a failure in the identification process, which failure forcibly releases the connection and prevents the recording of additional items of information pertaining to the toll call. This latter operation is desirable inasmuch as the failure of the automatic calling line identification means prevents the proper assessment of the toll charge for the call.

Assuming that adequate calling line identification information has not been received from the identifier circuit 6% and stored in the identifier sender 31%, the sender 310 operates, as described in detail in the above identified copending Clement et al. application and Harris application, to apply ground to the upper operating winding of a noidentification relay 3N1 through the closed contacts 3SD7 to operate this relay to close a plurality of contacts 3NI1 and 3NI3 and to open a pair of contacts 3NI2. The closure of the contacts 3NI3 completes a holding circuit extending to the lower winding of the relay 3N1 from the closed and grounded contacts 3RDS4. The closure of the contacts 3NI1 interconnects a terminal 331 with the tip conductor of the extended switch train through a coupling condenser, the terminal 331 being connected to a source of busy tone to provide an audible indication to the subscriber at the calling substation A that the connection cannot be completed. The opening of the contacts 3N2. opens up the outgoing loop circuit from the trunk circuit, thereby to prevent the extension of the connection to the called subscriber B. In response to the receipt of busy tone, the connection is released by the calling subscriber at the substation A to release the calling bridge relay 3GB and restore the remainder of the operated components in the trunk circuit to a normal condition. Incident to these releasing operations and as described in detail hereinafter, the end-of-call relay ZEC records an end-of-call code comprising simultaneous mark and space pulses on the magnetic tape of the trunk recorder 5th), and thereafter the stepping switch DC, the end-of-call relay ZEC, and the pulse assist relay 2PA cooperate to advance the magnetic tape in the trunk recorder 500 a predetermined number of steps controlled by the stepping switch DC.

However, assuming that adequate calling line identification information is received by the identifier sender and, in response to the storage thereof as described in detail in the above identified copending Clement et al. application or in the above identified copending Harris application, the identifier sender 31% supplies resistance ground to the wiper 3149a which is sufficient to maintain the start identification relay 38D operated but which is not sufficient to act as marking ground on the contact multiple individual to the trunk circuit with which the wiper 319a is in engagement. Further, the identifier sender 310 removes ground from the wiper 310C to open the operating circuit for the identify relay 311) so that this relay releases to open the contacts ZiDl, 2iD2, ZIDS, and 3ID1.

The opening of the contacts '3ID1 removes the source of direct holding ground for the start identification relay 3SD, but this relay remains operated over the resistance ground provided on the Wiper 310a by the identifier sender 310. The opening of the contacts 2ID1 removes grounded battery from the operating winding of the above five relay 6AF, thereby releasing this relay to open the contacts 6AF1 to 6AF5, inclusive. The opening of the contacts 2ID2 removes grounded battery from the path prepared by the selective operation of the relays 2T0 and ZTR extending to the operating winding of the relay 670, thereby releasing this cut-through relay for the party ten matrix 630 and thus effectively disconnecting this matrix from the input of the identifier circuit 690. The opening of the contacts 21133 removes the identification potential from the HS lead of the extended switch train and from the energized party matrices, such as the matrices 610, 620, and 630. Accordingly, in response to the release of the identify relay 3113, the identification matrix circuit 680 and the party matrix switching circuit 600 together with the identifier circuit 693 are effectively released for use in conjunction with the identification of other calling substations.

Incident to the removal of ground from the Wiper 3100 and the consequent release of the identify relay 31D, the identifier sender 310 initiates the transmission of four groups of mark pulses separated by space pulses to the mark pulse relay 3MK and the space pulse relay ZSP for intermittently operating these relays in conjunction with the second mark relay SMKS and the second space relay 3SPS to record groups of mark pulses separated by space pulses on the magnetic tape of the trunk recorder 500 in accordance with the values of the digits forming the directory number or designation of the calling substation A. In this manner, the trunk recorder 500 is automatically provided with digits forming the directory number of the calling substation in the event that the identifier sender 31th is provided with adequate identification information by the identifier circuit 690.

Following the completion of the transmission of this digital information from the identifier sender 316 to the trunk recorder 5%, resistance ground is removed from the wiper 310a to release the start identification relay 38D. In releasing, this relay opens the contacts ZSDi, ZSDB, 28134, SSDZ, BSD-3, 3SD4, 38136, and 3SD7 and closes the contacts ZSDZ, 38131, and 3SD5. The operations of the contacts 3SD4, 3SD5, and 3SD6 prepare the above described operating circuits for the start identification relay BSD and the identify relay 31D. The opening of the contacts 3SD7 interrupts the above described operating circuit for the no-identification relay 3N1. The opening of the contacts SSDZ interrupts the above described operating circuit for the mark relay SMK, and the concurrent closure of the contacts 3SD1 interconnects the operating winding of the mark relay 3MK with the prepared pulsing path extending to the contacts 232 controlled by the trunk timing mechanism. The opening of the contacts 3SD3 interrupts the above described operating circuit for the identification complete relay 31C, but this relay remains operated over the holding circuit completed at the contacts 3IC1. The opening of the contacts 2SD3 interrupts the above described circuit extending to the identifier sender 319 for operating the space relay ZSP, and the concurrent closure of the contacts 2SD2 prepares another operating path for the space relay 2SP. The opening of the contacts ZSDd removes the source of holding ground for the release delay relay 2RD, but this relay is maintained operated by the closed contacts ZCBZ.

The opening of the contacts 2SD1 interrupts the above described holding circuit for the operated party digit register relays 2T0, ZTR, and ZSTT so that these relays release to restore the contacts controlled thereby to a normal condition. The restoration of the contacts controlled by these relays to their normal condition aids in conditioning the trunk circuit for another cycle of recording operation, but produces no other useful function at this time.

The trunk circuit is now in condition to record duration information in the trunk recorder 500 under the control of the timing mechanism individual to this trunk circuit. The release of the start identification relay 35D, in closing the contacts 3SD1, prepares a path extending through the closed contacts 2PU4 and 210% to a pair of contacts 232 controlled by the timing mechanism. As designated above, the contacts 232 are first closed after an interval of approximately sixty-five to sixty-seven seconds following the energization of the timer clutch 230 in response to the receipt of answering supervisory signals from the remote switching equipment 300. It will be noted that this interval is five to seven seconds longer than the desired one minute interval at which pulses are to be recorded in the trunk recorder 50% as a representation of the duration of the toll call. However, this additional time interval is added to the first minute to be recorded in trunk recorder 509 to allow for the disconnect time of the switch train in response to the release of the connection at the termination of the toll call. If this interval allowed for disconnect time were not provided, it would be possible for a subscriber to go on-hook at a time substantially at the end of a metered one minute interval, and the disconnect time of the extended switch train would be such as to permit the recording of an additional one minute duration impulse in the trunk recorder 500, thereby to cause a toll charge to be assessed for an additional minute of conversation time. By the provision of a first pulse representing duration information which is transmitted a time interval following a sixty second interval which is approximately equal to the greatest disconnect time of the switch train, this improper assessment of an additional one minute interval to the subscriber is prevented.

Accordingly, after an interval of between sixty-five to sixty-sevent seconds following the receipt of answer supervision, the contacts 232 close to extend ground over the circuit including the closed contacts 21(34, 2PU4, and 38131 to operate the mark relay 3MK and then the second mark relay SMKS so that a mark pulse is recorded on the magnetic tape in the trunk recorder 500, and the drive magnet 630 is operated to condition the magnetic tape for being advanced a single step. Upon release of the contacts 232, the mark relays 3MK and SMKS sequentially release to release the drive magnet 530 so that the magnetic tape is advanced a single step following .the recording of the first mark pulse. Thereafter, the contacts 232 close at sixty second intervals so that a mark pulse is recorded in the trunk recorder 590 at the end of each one minute interval, thereby to provide a number of mark pulses on the magnetic tape corresponding to the number of one minute interval that the toll connection was maintained.

The recording operations of the trunk recorder are terminated in response to the release of the extended toll connection, and, incident to the release of the trunk circuit, an end-of-call code comprising simultaneous mark and space pulses is recorded on the magnetic tape to indicate the end of the items of information pertaining to the toll call. The magnetic tape is then advanced a counted number of steps under the control of the pulse assist relay ZPA, the end-of-call relay 2EC, and the stepping swich DC to provide a fixed or predetermined space separating the items of information pertaining to the toll call fromthe items of information to be recorded pertaining to a succeeding toll call. More .specifically, when the calling substation A goes on-hook, the calling bridge relay 3GB is released to restore the contacts controlled thereby to their normal position, in which position the contacts 2CB2 are opened to interrupt the operating circuit for the slow-to-release release delay relay 2RD.

After a suitable time delay determined by the slow-torelease characteristic of the release delay relay 2RD, this relay releases to restore the contacts controlled thereby to their normal position. The opening of the contacts 3RD1 removes ground from the sleeve lead of the eX- tended switch train to permit the switch train extended to the trunk circuit to restore to its normal condition. The closure of the contacts 2RD} completes an operating circuit for the space relay 2SP extending through the closed contacts 2RDS2 and 2IC2 so that the space relay 28F and the second space relay 3SPS are sequentially' operated to energize the space pulse head 540 for recording a space pulse on the magnetic tape immediately following the group of mark pulses representing the duration of the tool call. The sequential operation of these relays further energizes the drive magnet 530 to condition the drive mechanism for advancing the magnetic tape a single step.

In opening the contacts 2RD2 in response to the release of the release delay relay 2RD, the source of main holding ground is removed from the trunk circuit so that the relays 2PT, 2LD, 38R, SSRS, and 2SRT release to restore their contacts to a normal condition. The release of these relays performs no useful function at this time other than in conditioning the trunk circuit for a cycle of operation as described above. The opening of the contacts 3RD2, 2SRT2, and 2SRS1 terminates operation of the timer to prevent the recording of additional duration information in the trunk recorder 500.

In addition to removing the source of main holding ground from the trunk circuit, the opening of the contacts 2RD2 interrupts the operating circuit for the slowto-release release delay slave relay ZRDS. This relay, after a suitable time interval, releases to close the contacts ZRDSI, 3RDS1, 3RDS2, and 3RDS3 and to open the contacts 2RDS2 and 3RDS4. The closure of the contacts ZRDS! prepares an operating circuit for the pulse assist relay 21 A and one operating Winding of the differential end-of call relay 2EC, which path includes the closed contacts ZRDTI and 2PB1 and extends to the home position contacts in the bank of contacts associated with the wiper 2DC4 of the stepping switch DC. The opening of the contacts 2RDS2 interrupts the above described operating circuit for the space relay 2SP so that this relay and the second space relay 3SPS release to deenergize the drive magnet 530, thereby to advance the magnetic tape in the trunk recorder 500 a single step following the recording of the space pulse disposed after the group of mark pulses representing the duration information. The closure of the contacts 3RDS2 reapplies ground to the sleeve terminal of the trunk circuit extending from either of the closed contacts 3RDT1 or 3DC2. The reapplication of ground to the sleeve lead at this time cannot hold the switch train extended to the trunk circuit inasmuch as the switch train has released in the slow-to-release interval of the release delay slave relay ZRDS following the opening of the contacts 3RD1 described above. However, the reapplication of ground to the sleeve terminal of the trunk circuit at this time prevents the seizure of the trunk circuit for use in recording items of information pertaining to a subsequent toll call until' such time as the trunk circuit has been fully restored to its normal condition, the end-of-call code has been recorded in the trunk recorder 500, and the magnetic tape therein advanced to a position conditioned to receive these next items to be recorded. The closure of the contacts 3RDS1 again connects the resistor 351 and the condenser 352 across the repeat coil 320 to provide a termination for the trunk circuit.

The closure of the contacts 3RDS3 completes an operating circuit for the release or reset magnet 3DCZ of the stepping switch DC which extends through the closed contacts 3EC4 and the closed off-normal contacts 3DC1. In response to energization of the magnet 3DCZ, the contacts 4DCZ1 are closed to provide a delayed alarm signal, as described above, and the plurality of wiper 2DC1, 2DC2, 2DC3, and 21303 are mechanically restored to their normal home position. In restoring the wipers to their normal position, the contacts 3DC1 and 3DC2 are opened. The opening of the contacts 3DC2 removes one source of ground from the sleeve lead of the trunk circuit, but ground is maintained thereon by the closed contacts SRDTI. The opening of the contacts 3DC1 interrupts the above described operating circuit for the release magnet 3DCZ so that this relay releases to open the contacts 4-DCZ1.

The restoration of the wipers of the stepping switch -DC to their normal position conditions this stepping switch for reuse in counting intermittent operations of 

